JP2010528782A - Wearable VAD controller with spare battery - Google Patents

Abstract

Disclosed is an apparatus and method for providing standby power to a ventricular assist device. In one embodiment, the device comprises a primary power source that powers the device, and a controller that has a spare battery for powering the device when power to the device of the primary power source is insufficient. The controller housing is configured for use outside the patient's body by a percutaneous cable leading to the device. In another embodiment, the method includes powering the device with a primary power source, monitoring the power supplied to the device, and in the controller housing when the power being monitored is insufficient for the device. Powering the device with a standby power source disposed in the device, wherein the device is placed subcutaneously in the patient's body, the controller housing is placed outside the patient's body, and the device and the controller housing are percutaneous Connected by cable. Other embodiments are also disclosed.
[Selection] Figure 1

Description

Ongoing cross-reference of prior patent applications

  This application is filed on June 6, 2007, by Jim Lee, et al. Under Section 119e of US Patent Law, entitled “WEARABLE VAD CONTROLLER WITH RESERVE BATTERY” filed June 6, 2007. And claims the benefit of US Provisional Patent Application No. 60 / 933,607, which is hereby incorporated by reference.

  The present invention relates to an apparatus and method for supplying a reserve power source to a ventricular assist device or a mechanical circulation support device.

  A ventricular assist device (VAD) pumps blood in parallel with the original ventricle of the human heart. This device provides blood flow to the human body when the patient's own heart is damaged. In a typical left VAD graft configuration, blood is drawn from the left ventricular apex and returned to the ascending aorta at high pressure. Thus, VAD takes up a significant portion of the work performed by the original heart without removing the original heart.

  VAD may be used for temporary applications, for example, as a connection to heart transplantation or as a connection to recovery of the original heart. However, many of the greatest uses for VAD are long-term use over the life of a patient. This device is known as the use of a permanent therapy (DT) device.

  Several VAD systems are commercially available that use batteries to power the controller and pump. For example, Thoratec HEARTMATE I (registered trademark) and HEARTMATE II (registered trademark) of Thermedics, Inc. and WorldHeart Novacor (registered trademark) of WorldHeart Corporation are commercially available products. Normally, two power supplies are required to operate these systems safely. Conventional systems are implemented using two external batteries, or one external battery and a power supply from an AC power source, and must always be connected to the patient.

  The development of fully implantable systems, including a bridge battery and an external power source supplied through a transcutaneous energy system, has reached the research or commercialization stage. Examples of such systems are the implantable cardiac assist device ARROW LIONHEART ™ from Pennsylvania State University School of Medicine, Jarvik 2000 (registered trademark) from Jarvik, Abiomed AbioCor (registered trademark) Total Artificial Heart from Abiomed, Inc., and the like. None of these systems apply the concept of spare batteries to externally mounted controllers.

  One embodiment of the present invention provides an apparatus for supplying a reserve power source to a ventricular assist device. The apparatus includes: a primary power source that supplies power to the ventricular assist device that is subcutaneously disposed in a patient's body; and the primary power source for supplying power to the ventricular assist device when the power supply to the ventricular assist device is insufficient. A controller containing a reserve battery, wherein the controller housing is configured to be used outside the patient's body by a percutaneous cable leading to the ventricular assist device.

  Another embodiment provides a method for providing a reserve power supply to a ventricular assist device. The method includes powering the ventricular assist device by a primary power source, monitoring power supplied to the ventricular assist device by the primary power source, and power being monitored to the ventricular assist device. Powering the ventricular assist device with a reserve power source disposed within the controller housing, if sufficient, wherein the ventricular assist device is disposed subcutaneously within the patient's body, the controller housing being external to the patient's body. The ventricular assist device and the controller housing are connected by a percutaneous cable.

  Yet another embodiment provides an apparatus for supplying a reserve power supply to a mechanical circulation support device. The apparatus includes a primary power source that supplies power to the mechanical circulation support device that is subcutaneously disposed in a patient's body, and the mechanical circulation support device when power supply to the mechanical circulation support device is insufficient. A controller housing containing a spare battery for powering the device, the controller housing configured to be used outside the patient's body by a percutaneous cable leading to the mechanical circulation support device.

  Yet another embodiment provides a method for supplying a reserve power supply to a mechanical circulation support device. The method supplies power to the mechanical circulation support device by a primary power source, monitors power supplied to the mechanical circulation support device by the primary power source, and the monitored power is supplied to the mechanical circulation support device. Powering the mechanical circulatory support device with a reserve power source located in the controller housing, if insufficient for the support device, the mechanical circulatory support device placed subcutaneously in the patient's body The controller housing is disposed outside the patient's body, and the mechanical circulation support device and the controller housing are connected by a percutaneous cable.

  Other embodiments are also disclosed.

  Illustrative embodiments of the invention are shown in the drawings.

FIG. 4 is an exploded view of an exemplary controller with a spare battery. FIG. 2 illustrates the example controller of FIG. 1 being used by a patient.

  Various embodiments, methods, and devices for supplying a reserve power source to a ventricular assist device (or mechanical circulation support device) are disclosed. To provide an improved device for VAD patient care, a reserve power supply can be provided in the controller housing.

  The motorized ventricular assist device usually requires an external power source such as a battery for a patient to move and an AC power source connection when the patient is sleeping or the like. Usually, an electronic controller is required to control the pump device and modulate external power to the pump device. In such a system, the controller can be placed outside the human body. Generally, at least two power sources are required to operate the system safely. If a failure or discharge occurs in the first power source, the pump continues to operate without interruption from the second power source. Conventional VAD systems have used either two external batteries or one external battery and an AC power connection to provide redundancy for safe operation.

  Referring to FIGS. 1 and 2, to provide redundant power to mechanical circulation support devices, including ventricular assist devices, collectively referred to as pump 15 or pump system 15 below, external controller 5 is a spare in the exemplary embodiment. A battery 10 may be included. In one embodiment, a reserve battery 10 for operating the pump system 15 is in the controller 5. With this configuration, the patient need only manage two external packages instead of three “external packages”. These two “packages” have either an external controller 5 and one external battery 20 (FIG. 2) or an AC power connection with the external controller 5. (For example, AC power can be supplied to the controller 5 from the external power connection 45B.) Conventionally, for safety reasons, the patient and the controller and two external power sources, for example, two external batteries 20 or one external battery 20 and it are There was a need to manage another AC power connection.

  An exemplary embodiment of a controller 5 having a spare battery 10 is shown in FIG. The reserve battery 10 built in the controller housing 5 shown in FIG. 1 may be a rechargeable battery or other suitable battery. When there is no external power applied to the controller 5, such as the external battery 20, the VAD pump The system 15 is activated to continue the blood supply.

  With continued reference to FIG. 1, at least one printed circuit board 25 may be provided in the housing element 30 of the controller 5. Such one or more printed circuit boards 25 can be configured to control the pump system 15. The one or more printed circuit boards 25 can be configured to monitor the received power supply from the external battery through the port 40A of the external power connection unit 45A or from the AC power source through the port 40B of the external power connection unit 45B. One or more printed circuit boards 25 can be configured to monitor power feed to the pump 15 through the port 35 of the external power connection 45C. When a specified amount of power cannot be supplied to the pump system 15 from the primary or selected power source such as the external battery 20 (FIG. 2) or the AC power supply 45, the spare battery 10 is connected to supply power for operating the pump system 15. it can. The controller 5 may optionally include an alarm unit 104, such as an audio alarm unit, an image alarm unit, or a combination thereof that issues an alarm when the power from the primary, secondary, or combination of primary and secondary falls below a threshold. Good.

  In one embodiment, the external power connections 45A and 45B used for external power and communication can be interchanged. External power connections 45A and 45B can be directly connected to ports 40A and 40B. For the controller 5, those external power connections 45A and 45B can be configured in another way. For example, the ports 40A and 40B can be omitted, and the external power connections 45A and 45B can be directly connected to the controller 5. The external power connection 45C leading to the pump 15 may be directly connected to the port 35. Alternatively, the external power connection unit 45 </ b> C can be configured for the controller 5 by another method. For example, the port 35 can be omitted, and the external power connection unit 45C can be directly connected to the controller 5.

  Referring again to FIG. 1, in one embodiment, a controller battery 50 can be provided in the housing. The controller battery 50 can be configured to power various components of the controller 5. Such components include one or more components on the printed circuit board 25, such as switches, audio displays, image displays 55, and the like. The alarm unit 10A may be integrated with the audio and / or image display 55. The sound and / or image display 55 may include the alarm unit 10A described above. In other words, in contrast to the power supplied from the spare battery 10 to the pump device 15, the battery 50 can supply power for calculation functions and other electronic functions.

  The controller 5 including the spare battery 10 can supply emergency power for operating the pump 15 in various situations. For example, if the user tries to use the exhausted battery 20 by mistake, there is a possibility that the battery 20 may run out of power or become insufficient without a means for charging the battery 20 or connecting to an AC power source. is there. Further, for example, the user may insert the battery in the reverse direction, remove the wrong battery from the plug, or remove the AC power from the power supply of the pump 15. In the conventional system, if the user misoperates two power supplies, the pump 15 stops operating. In contrast, the controller 5 with the spare battery 10 does not give the user the chance to accidentally avoid powering the pump 15. The user can rely on a single external power supply 45A or 45B. When the controller 5 determines that the pump 5 is not receiving power or is insufficient, the spare battery 10 is temporarily activated, and sufficient power can be supplied to operate the pump 15. In one embodiment, the reserve battery 10 operates the pump 15 for approximately 30 minutes when power from an external power source, for example, power from the external power connections 45A and 45B is not supplied or insufficient to power the pump 15. Have power to make. In another embodiment, the standby battery 10 may operate for about 15 to 20 minutes, or at least 50 minutes.

  A reserve battery 10 built into the controller 5 allows the patient to operate the pump 15 with a single external battery. As a result, the weight carried by the patient can be reduced. Alternatively, the operating time can be extended by switching between two external battery packs.

  Those skilled in the art and clinical users of implantable mechanical circulatory support devices will appreciate that the ability to continue delivering blood for some time without power to the controller is an advance over existing devices.

  Also, 1) left ventricular assist device, 2) right ventricular assist device, 3) complete artificial heart (removal of the original heart), 4) mechanical assist blood placed in the circulatory system that does not directly assist the ventricle Those skilled in the art will appreciate that methods and apparatus that incorporate a spare battery in the controller housing are equally applicable to mechanical circulation support devices other than VAD, including pumps.

5 External Controller 10 Spare Battery 20 External Battery 25 Printed Circuit Board 30 Housing 35 Port 40A, 40B Port 45A, 45B, 45C External Power Connection (External Power Supply)
50 Controller battery 55 Display

Claims (22)

A device for supplying a backup power to a ventricular assist device,
The device is
A primary power source for powering the ventricular assist device placed subcutaneously in the patient's body;
A controller in which a spare battery for supplying power to the ventricular assist device when power supply to the ventricular assist device of the primary power supply is insufficient is incorporated in a controller housing,
The controller housing is configured to be used outside a patient's body by a percutaneous cable leading to the ventricular assist device;
A device characterized by.   The apparatus of claim 1, further comprising a controller battery disposed within the controller housing, wherein the controller battery is configured to power electronic components of the controller.   The apparatus according to claim 2, wherein the electronic component of the controller includes at least one of an audio display and an image display.   The apparatus of claim 2, wherein the mechanical pump of the ventricular assist device is not included in the electronic component of the controller.   The apparatus of claim 1, wherein the primary power source is a battery.   6. The device of claim 5, wherein the ventricular assist device operates safely with only two external packages.   The apparatus of claim 6, wherein the two external packages include the controller housing and the primary power source.   The apparatus of claim 1, wherein the primary power source is an AC power source.   9. The device of claim 8, wherein the ventricular assist device operates safely with only one external package.   The apparatus of claim 9, wherein the one external package includes the controller housing. And further comprising at least one printed circuit board, wherein the at least one printed circuit board is configured to monitor power supplied to the ventricular assist device, wherein the at least one printed circuit board is provided by the primary power source. Switching to the reserve battery to power the ventricular assist device when power is insufficient for the ventricular assist device;
The apparatus of claim 1.   The apparatus according to claim 1, further comprising an alarm unit. A method of supplying a backup power to a ventricular assist device,
The method
Powering the ventricular assist device with a primary power source;
Monitoring the power supplied to the ventricular assist device by the primary power source;
Powering the ventricular assist device with a reserve power source disposed in a controller housing when the monitored power is insufficient in the operation of the ventricular assist device;
The ventricular assist device is placed subcutaneously inside the patient's body, the controller housing is placed outside the patient's body, and the ventricular assist device and the controller housing are connected by a percutaneous cable;
A method characterized by.   The method of claim 13, further comprising providing the primary power source as a battery.   15. The method of claim 14, further comprising actuating the ventricular assist device with only two external packages.   The method of claim 15, further comprising actuating the ventricular assist device with the controller housing and the primary power source.   The method of claim 13, further comprising providing the primary power source as an AC power source.   18. The method of claim 17, further comprising operating the ventricular assist device with only one external package.   19. The method of claim 18, further comprising actuating the ventricular assist device with the controller housing. Activating the controller using a primary power source with at least one printed circuit board disposed in the housing;
Monitoring the power supplied to the ventricular assist device by components on the at least one printed circuit board;
When the power supplied by the primary power supply is insufficient for the ventricular assist device, switching from the primary power supply to a spare battery located in the controller to power the ventricular assist device; Further including,
The method according to claim 13. A device for supplying a backup power to a mechanical circulation support device,
The device is
A primary power source for supplying power to the mechanical circulation support device placed subcutaneously in the patient's body;
A spare battery built in a controller housing for supplying power to the mechanical circulation support device when power supply to the mechanical circulation support device of the primary power supply is insufficient,
The controller housing is configured to be used outside a patient's body by a percutaneous cable leading to the mechanical circulation support device;
A device characterized by. A method of supplying standby power to a mechanical circulation support device,
The method
Supplying power to the mechanical circulation support device by a primary power source;
Monitoring the power supplied to the mechanical circulation support device by the primary power source;
Powering the mechanical circulation support device with a reserve power source disposed in a controller housing when the monitored power is insufficient for operation of the mechanical circulation support device;
The mechanical circulatory support device is placed subcutaneously inside the patient's body, the controller housing is placed outside the patient's body, and the mechanical circulatory support device and the controller housing are connected by a percutaneous cable;
A method characterized by.

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